RU2166189C2 - Automated flash-temperature test technique and facility - Google Patents

Abstract

FIELD: thermal physics. SUBSTANCE: proposed technique envisages use of parallel-functions head. Test vessels are filled with pre-tested liquids and closed with test lids equipped with temperature recording and flash-point displaying devices as well as with test-lid turning and liquid- stirring devices. Test inserts prepared in this way are entered in tempering device, and split and/or contacting joints are provided between parallel- functions head of automatic machine and test insert so as to ensure that there is electric contact between temperature recording and flash-point displaying devices and that stirring devices and test lid are mechanically coupled with their respective actuators whenever required and uncoupled from them upon completion of ignition process and flash-point test procedure. EFFECT: facilitated test procedure, simplified design of facility, provision for fast change of samples. 12 cl, 2 dwg

Description

 The invention relates to a method and apparatus for automatically testing the flash point in a closed crucible and is used to determine the flash point of flammable liquids, liquids with suspended solids, lubricating oils, liquids that are prone to create a surface film and other liquids.

 Finding out the flash point is an important criterion for determining the flammability and explosion hazard of this substance. Flash point is the lowest temperature at a set barometric pressure of 101.3 kPa, at which, observing the prescribed test conditions, the sample vapor is ignited using an ignition flame.

 To ensure comparability of these flash point determinations at different locations, the flash point test setups were rated according to international standards.

 The most widely used methods in the world are according to Pensky Martens (e.g. according to DIN 51758, ASTM D 93, ISO / EN 2719), Abel (e.g. according to IP 113. ISO 13736). Abel Pensky (e.g. according to DIN 51755/53213) and TAG (e.g. according to ASTM D 56) with a closed test insert due to good reproducibility.

 These standards define all the decisive sizes of the plants, the conditions of heating and measurement. An important component of the installation is the test insert, which consists of a crucible and a locking cover with a rotary valve cover, which is necessary to open the holes of the test cover through which ignition passes into the space above the liquid.

 In accordance with the development of technology and the necessary rationalization, flash points are currently determined mainly by automated installations.

 A common drawback of all known methods is the limitation of automation on heating, an attempt to ignition and recording the flash point. Automation with these methods does not adequately cover the preparatory phase of the sample change.

 Therefore, the invention proceeds from the task of creating a method and device that allows a simpler and faster change of samples, the greatest reduction in manual operations, the reduction of subjective effects on the preparation and testing of flash points, simple, reliable and inexpensive production, application and maintenance of the device.

 The invention solves this problem through signs in terms of defining the claims of Clause 1 and Clause 8 in connection with the attributes in each specific generic concept.

 Suitable possibilities for carrying out the invention are contained in the claims.

 A significant advantage of the invention is the use of the head of parallel functions. This head allows the greatest reduction in manual operations and the exclusion of operator influences. The test vessels are filled with pre-tested liquids and closed with test caps, which are equipped with means for recording temperature and indicating flash points, as well as means for turning the test cap, mixing, and thereby form test inserts. Thus, the prepared test inserts are inserted into the tempering device and detachable connections and / or contacts are created between the head of the parallel functions of the machine and the test insert so that the means for recording temperature and indicating the flash temperature receive an electrical contact and, if necessary, the means of mixing and turning the test cover mechanically connected to the drives and were again disconnected after completion of ignition and after completion of the test the pace ture flashes.

 Since the temperature sensor and the flash temperature indicator are inserted after filling the sample and before inserting it into the heating device, the subsequent stage of changing the samples in the automated device is not affected by the loads. By current technology standards, the necessary manual operations are replaced by a single introduction of the head of parallel functions. Since the test insert filled with the test liquid is the most leakproof, the flammable parts of the test liquid cannot accidentally evaporate, which creates a completely new opportunity to keep the prepared test insert for a longer period in a previously required cooled state.

 When this insert is inserted into the tempering device, the closed state is maintained continuously until the first (according to the standards) ignition test. By providing thus prepared samples (manual or automatic) gives further opportunities to save time.

 An easily and inexpensively manufactured and reliably reproducible operating device that complies with national and international standards is created by the fact that the aggregate test device consists of a stationary head of parallel functions and a mobile one completely detachable from the head of parallel functions of the test insert. At the same time, the test insert has at least one temperature sensor in the pre-equipped condition, at least one flash temperature indicator, and the head of parallel functions is equipped with contacting elements for creating electrical connection with temperature sensors and flash temperature indicators, and it is also equipped with at least one communication element for creating mechanical connection between the drive of the mixer and the mixer itself.

 The invention is explained in more detail by examples of implementation, which are partially shown in the following drawings.

Shown on:
FIG. 1 is a schematic representation of an aggregate device with a parallel function head separated from the test insert (sample loading phase);
FIG. 2 is a schematic illustration of a test insert and a head of parallel functions connected to each other (flash temperature test phase).

 As shown in FIG. 1, the aggregate device 1 consists of a stationary head of parallel functions 2, which is connected to a control and evaluation unit not shown in the drawings, and also of a mobile test insert 3, which is completely separated from the head of parallel functions 2 during the loading phase by samples.

 The mobile test insert 3 consists of a test vessel 4 in which the test fluid 5 is located and which is covered by the test cover 6. The agitator 7 is lowered into the test fluid. The test cover 6 in this example is equipped with a rotary valve 8, which serves to open or close the ignition hole. In addition, a sleeve 9 is attached to the test cover 6, which is designed to install at least one temperature sensor 10 and at least one flash temperature indicator 11.

 On the sleeve 9 there are electrical contacts of the temperature sensor 10 and the flash temperature indicator 11. The temperature sensor 10 passes through the bottom of the sleeve 9 into the test liquid 5, and the flash temperature indicator 11 - into the space above the test liquid 5. Naturally, there is such an opportunity to install the temperature sensor 10 and flash temperature indicator 11 directly without sleeve 9 and provide them with suitable contacts. The drive shaft 12 of the mixer 7 passes through the test cover 6. The test insert 3 is inserted into the tempering device 13, which provides heating or (in certain applications) cooling.

 In this example, the head of the parallel functions 2 is equipped with contacting elements 14, which are designed to interact with the contacts of the temperature sensor 10 and with the contacts of the flash temperature indicator 11. The head of the parallel functions 2, in addition, is equipped with a stirrer drive 15, which has a coupling element 16 for mechanical connection with a drive shaft 12 of the agitator 7. The drive of the rotary valve 17 with the control element 18 is attached to start the rotary valve.

 The ignition device 19 in this example is also located at the head of the parallel functions 2 and is installed in such a way that when it connects the head of the parallel functions 2 to the test insert 3 it enters the ignition hole 20, as shown in FIG. 2. Additionally, in this example, an additional indicator of flash temperature 21 is attached above the incendiary hole, which provides an additional indication above the incendiary flame and outside the test insert 3. Implementation can also be done by thermal indication, as well as, for example, by automatically observing the ignition at this place. Such a case of ignition outside test insert 3 may be caused, for example, by high vapor pressure in test insert 3 or by a delayed start of ignition (the liquid may already boil). In this case, it is not ensured that ignition of the ignited vapor mixture occurs inside the test insert 3 and thus cannot be detected by the usual indication using the flash temperature indicator 11. In one of the further embodiments, which is not shown in the drawings, the ignition 19 is attached to test insert 3, having connecting elements to the head of parallel functions 2 or directly to energy carriers, such as, for example, gas and / or electricity. In this embodiment, under certain circumstances, the rotary valve 8, the actuator of the rotary valve 17 and the control element 18 may fall off.

 The following describes the operating principle of an aggregate device in a time sequence. After filling the test vessel 4 with the test fluid 5, the test insert 3 is closed according to the norms of the test cover 6 with a rotary valve 8 and a sleeve 9 with a temperature sensor 10 and a flash temperature indicator 11. The layout is inserted into the tempering device 13. Next, the head of parallel functions 2 is inserted manually or automatically way. Thus, all necessary connections and positioning are automatically carried out. These are individually electrical contacting for transmitting measured values of a sample temperature and electrical contacting for transmitting measured values for indicating a flash temperature. In the future, the ignition, which was meanwhile removed from the test cover, is put into the required initial position (alternatively, the ignition can remain on the test cover, but in this case, when changing the samples, the connections to the power system must be detachable), a power circuit between the agitator drive 15 and the mixer 7 itself and the positioning of the control element 18 of the drive of the rotary valve 17 is made to open / close the rotary valve 8.

 The invention is not limited to the exemplary embodiments provided herein. On the contrary, it is possible by expediently combining the shown means and signs of further options, without going beyond the scope of the invention.

Claims (12)

 1. A method for automated testing of the flash point, in which the test liquids are tempered in closing test vessels, subjected to an ignition test, and upon successful ignition, flash points are recorded, characterized in that the test vessels are filled with pre-tested liquids and closed with test caps that are equipped with temperature recording means and indication of flash temperature, as well as means for turning the test lid and mixing liquid and thereby form test inserts, thus prepared test inserts are inserted into the tempering device and create detachable connections and / or contacts between the head of the parallel functions of the machine and the test insert so that the means for recording temperature and indicating the flash temperature receive an electrical contact and re-disconnected after completion of ignition and after testing the flash point.  2. The method according to claim 1, characterized in that the means for recording the temperature and indicating the flash temperature are connected to the head of the parallel functions and to the signal analysis unit by means of electrical contacts only for the duration of the test insert in the tempering device.  3. The method according to claim 1, characterized in that for changing the samples, the ignition is disconnected from the test cover using a controlled drive.  4. The method according to claim 1, characterized in that the electrical contacting, mechanical connection, positioning of the ignition and rotation of the test cover is performed by lowering and / or installing the head of parallel functions.  5. The method according to claim 1, characterized in that in addition to indicating the flash temperature inside the test insert, a further indication of the flash temperature outside the test insert is carried out.  6. The method according to claim 5, characterized in that the additional indication of the flash temperature is produced above the ignition hole.  7. The method according to claim 1, characterized in that the means of mixing and turning the lid are connected with the drives mechanically.  8. Device for automated testing of flash point, consisting of a test vessel that contains the test fluid and is configured to close the test cover with a stirrer, a temperature sensor and an indicator of the flash temperature, tempering device and ignition, characterized in that the total device consists of a stationary head parallel functions and a mobile test insert, the test insert being equipped with a temperature sensor in the pre-equipped state the flash point indicator, and to the simultaneous function head attached contacting elements to create an electrical connection with the temperature sensor and flash point indicator and at least one coupling element for creating a mechanical connection between the actuator and the agitator stirrer itself.  9. The device according to p. 8, characterized in that a rotary valve actuator with a control element is attached to the head of the parallel functions.  10. The device according to p. 8, characterized in that the ignition is additionally attached to the test insert, equipped with communication elements for connecting to the head of parallel functions.  11. The device according to claim 8, characterized in that the temperature sensor and the flash temperature indicator are located inside the sleeve.  12. The device according to claim 8, characterized in that outside the test insert above the ignition hole there is an additional indicator of the flash temperature.

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